Spatial distribution of DNA loop attachment and replicational sites in the nuclear matrix (original) (raw)
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Nuclear skeleton, DNA domains and control of replication and transcription
EJB Reviews 1991, 1991
Chromosomal DNA is organized in loops or domains of about 100 kb. Their ends seem to be attached to special protein skeletal structures. The DNA-attachment sites can be subdivided into permanent and transient types. The permanent or constitutive attachment sites, which are retained in all types of cells (including those inactive in replication and transcription), either coincide with or are located close to replication origins. This observation provides a simple way for isolation of DNA fragments containing replication origins. Such fragments from the chicken a-globin gene domain and other regions of the chicken genome contain DNA sequences which interact with nuclear proteins present in dividing cells, but absent from non-dividing cells. Several new consensus sequences interacting with nuclear proteins were detected. The 5' end region of the a-globin gene domain containing a replication origin was found to possess enhancer activity lacking tissue specificity. Hence, the domain organization of DNA is related to the organization of replication process. Other sets of data indicate that the integrity of DNA domains is important for maintaining transcription within the domain. According to these data, even a single nick at an distance of about 100 kbp seems to be sufficient for blocking transcription within the whole domain at the stage of RNA elongation. Thus, topological integrity of DNA may be an important factor involved in formation of active chromatin.
Cell-type-specific organization of nuclear DNA into structural looped domains
Journal of Cellular Biochemistry, 2011
In the interphase nucleus of metazoan cells the DNA is organized in supercoiled loops anchored to a proteinaceous substructure known as the nuclear matrix (NM). The DNA is anchored to the NM by means of non-coding sequences of variable length known as matrix attachment regions or MARs operationally classified in structural-constitutive, resistant to high-salt extraction and transient-functional, non-resistant to high-salt extraction. The former are also known as true loop attachment regions or LARs that determine structural DNA loops. The DNA-NM interactions define a higher order structure within the cell nucleus (NHOS). We studied in a comparative fashion the NHOS in two primary cell types from the rat: hepatocytes and naive B lymphocytes, by analyzing the topological relationships between the NM and a set of eight short gene sequences located in six separate chromosomes and as such representing a coarse-grained, large-scale sample of the actual organization of nuclear DNA into structural loop domains. Our results indicate that such an organization is cell-type specific since most of the gene sequences studied showed significant differences in their relative position to the NM according to cell type. Such cell-type specific differences in the NHOS have no obvious correlation with the tissue-specific transcriptional activity of the corresponding genes, supporting the notion that permanent, structural DNA loops are different from transient, functional DNA loops that may be associated with transcription.
Mapping replicational sites in the eucaryotic cell nucleus
The Journal of cell biology, 1989
We have used fluorescent microscopy to map DNA replication sites in the interphase cell nucleus after incorporation of biotinylated dUTP into permeabilized PtK-1 kangaroo kidney or 3T3 mouse fibroblast cells. Discrete replication granules were found distributed throughout the nuclear interior and along the periphery. Three distinct patterns of replication sites in relationship to chromatin domains in the cell nucleus and the period of S phase were detected and termed type I (early to mid S), type II (mid to late S) and type III (late S). Similar patterns were seen with in vivo replicated DNA using antibodies to 5-bromodeoxyuridine. Extraction of the permeabilized cells with DNase I and 0.2 M ammonium sulfate revealed a striking maintenance of these replication granules and their distinct intranuclear arrangements with the remaining nuclear matrix structures despite the removal of greater than 90% of the total nuclear DNA. The in situ prepared nuclear matrix structures also incorpora...
Association of Chromosome Territories with the Nuclear Matrix
Journal of Cell Biology, 1999
To study the possible role of the nuclear ma- trix in chromosome territory organization, normal human fibroblast cells are treated in situ via classic isolation procedures for nuclear matrix in the absence of nuclease (e.g., DNase I) digestion, followed by chromosome painting. We report for the first time that chromosome territories are maintained intact on the nuclear matrix. In contrast, complete extraction of the internal nuclear matrix components with RNase treatment followed by 2 M NaCl results in the disruption of higher order chromosome territory architecture. Correlative with territorial disruption is the formation of a faint DNA halo surrounding the nuclear lamina and a dispersive effect on the characteristically discrete DNA replication sites in the nuclear interior. Identical results were obtained using eight different human chromosome paints. Based on these findings, we developed a fractionation strategy to release the bulk of nuclear matrix proteins under conditions where the chromosome territories are maintained intact. A second treatment results in disruption of the chromosome territories in conjunction with the release of a small subset of acidic proteins. These proteins are distinct from the major nuclear matrix proteins and may be involved in mediating chromosome territory organization. Key words: chromosome territory • chromosome painting • fluorescence in situ hybridization • DNA-rich nuclear matrix • nuclear matrix proteins This article is dedicated to Professor Donald S. Coffey on the occasion of his 40th year at
Nucleic Acids Research, 2005
The spatial organization of an $170 kb region of human chromosome 19, including CD22 and GPR40-GPR43 genes, was studied using in situ hybridization of a set of cosmid and PAC probes with nuclear halos prepared from proliferating and differentiated HL60 cells. The whole region under study was found to be looped out into the nuclear halo in proliferating cells. It is likely that the loop observed was attached to the nuclear matrix via MAR elements present at the flanks of the area under study. Upon dimethyl sulfoxide-induced differentiation of the cells the looped fragment became associated with the nuclear matrix. This change in the spatial organization correlated with the activation of transcription of at least two (CD22 and GPR43) genes present within the loop. The data obtained are discussed in the framework of the hypothesis postulating that the spatial organization of chromosomal DNA is maintained via constitutive (basic) and facultative (transcription-related) interactions of the latter with the nuclear matrix.
The Topography of Chromosomes and Genes in the Nucleus
Experimental Cell Research, 1996
of nucleosomes packed into a spiral or solenoid [2 -4]. At present several lines of evidence indicate that the However, more recent in situ analysis of cryopreserved nucleus is functionally compartmentalized into dis-nuclei reveals a more disorded structure made of ribcrete structures with defined properties. For instance, bons of zigzagging nucleosomes and not solenoids [5]; it is well established that the molecular machines inadditionally, 30-nm chromatin fibers have been seen volved in replication, transcription, and RNA proin transcriptionally inactive nuclei [6], but not in active cessing assemble into morphological entities but it renuclei [7], suggesting that chromatin in the nucleus mains unclear whether these correspond to autonomay switch from a condensed and ordered configuramous ''organelles'' or rather represent temporary tion to a more extended and disordered structure deaccumulations of either active factors recruited onto pending on transcriptional activity.
DNA is replicated at the nuclear cage
Journal of cell science, 1980
Structures resembling nuclei are released when HeLa cells are lysed in a detergent and 2 M salt. These nucleoids, which lack any organized membrane structure, contain all the nuclear DNA packaged within a cage of RNA and protein. Their DNA is supercoiled so that the linear DNA must remain unbroken and looped during lysis. Following digestion with the restriction endonuclease, EcoRI, cages and associated DNA were filtered free of unattached DNA. Pulse-labelled (i.e. newly synthesized) DNA remains preferentially associated with the cages. This association has been confirmed by autoradiography. When nucleoids are prepared for electron microscopy by the Kleinschmidt procedure the DNA spills out to form a skirt around the flattened cage. Labelling, which is restricted to the region of the cage after short pulses, extends out into the skirt as the labelling time increases. A model, based on the premise that replication takes place at the nuclear cage, is presented in the Appendix. The res...
Journal of Cellular Biochemistry, 2012
In the interphase nucleus of metazoan cells DNA is organized in supercoiled loops anchored to a nuclear matrix (NM). DNA loops are operationally classified in structural and facultative. Varied evidence indicates that DNA replication occurs in replication foci organized upon the NM and that structural DNA loops may correspond to the replicons in vivo. In normal rat liver the hepatocytes are arrested in G0 but synchronously re-enter the cell cycle after partial-hepatectomy leading to liver regeneration. Using this model we have previously determined that the DNA loops corresponding to a gene-rich genomic region move in a sequential fashion towards the NM during replication and then return to their original configuration in newly quiescent cells, once liver regeneration has been achieved. In the present work we determined the organization into structural DNA loops of a gene-poor region centered on c-myc and tracked-down its movement at the peak of S phase and after the return to cellular quiescence during and after liver regeneration. The results confirmed that looped DNA moves towards the NM during replication but in this case the configuration of the gene-poor region into DNA loops becomes reorganized and after replication only the loop containing c-myc resembles the original in the control G0 hepatocytes. Our results suggest that the local chromatin configuration around potentially active genes constraints the formation of specific structural DNA loops after DNA replication, while in non-coding regions the structural DNA loops are only loosely determined after DNA replication by structural constraints that modulate the DNA-NM interactions.
Sites of Replication of Chromosomal DNA in a Eukaryotic Cell
Proceedings of the National Academy of Sciences, 1972
In mouse cells (line P815), newly synthesized DNA labeled for 20-30 sec during exponential growth is found by electron microscope autoradiography at sites throughout the cell nucleus. These sites are relatively more concentrated in the peripheral region of the nucleus (averaged over a random population of S-phase cells), probably reflecting a higher local concentration of DNA in this region. Newly synthesized DNA is not preferentially associated with purified nuclear envelopes, but is found in a fraction of the chromosomal deoxynucleoprotein whose buoyant density in CsCl after formaldehyde treatment is about 1% lower than that of the deoxynucleoprotein peak. Kinetics experiments suggest that this material is a precursor of mature deoxynucleoprotein; it may represent regions of deoxynucleoprotein containing replicating DNA and the additional proteins involved in DNA replication. Other complexes of newly replicated DNA that are found in the interphase after phenol extraction of nuclei...